With a speed of 331 m/s and a frequency of 20 Hz
the wavelength is (331 m/s)/(20 Hz)=16,55 m .
The wavelength of a wave is calculated as the speed of the wave divided by its frequency. In this case, the wavelength is 331 m/s divided by 20 Hz, which equals 16.55 meters.
Color light waves differ in terms of their wavelength and frequency. Each color corresponds to a different wavelength within the electromagnetic spectrum. For example, red light has a longer wavelength and lower frequency than blue light. This difference in wavelength is what gives each color its unique appearance to the human eye.
The longest wavelength that a human can hear corresponds to a frequency of about 20 Hz, which is typically the lower limit of human hearing. Wavelength and frequency are inversely proportional; as frequency decreases, wavelength increases.
Color is related to frequency through the electromagnetic spectrum, where different colors correspond to different wavelengths and frequencies of light. As the wavelength of light decreases, the frequency increases, resulting in different colors being perceived by the human eye. In the visible light spectrum, red light has a longer wavelength and lower frequency, while violet light has a shorter wavelength and higher frequency.
The lowest frequency audible to the human ear is around 20 Hz. Using the formula v = fλ, where v is the speed of sound (330 m/s) and f is the frequency (20 Hz), we can solve for the minimum wavelength, which is 16.5 meters.
The wavelength of ultrasound can be calculated using the formula: wavelength = speed of sound / frequency. For ultrasound in human tissue with a frequency of 3.5 million Hz, the speed of sound in tissue is around 1540 m/s. Therefore, the wavelength would be approximately 0.44 mm.
Color light waves differ in terms of their wavelength and frequency. Each color corresponds to a different wavelength within the electromagnetic spectrum. For example, red light has a longer wavelength and lower frequency than blue light. This difference in wavelength is what gives each color its unique appearance to the human eye.
The longest wavelength that a human can hear corresponds to a frequency of about 20 Hz, which is typically the lower limit of human hearing. Wavelength and frequency are inversely proportional; as frequency decreases, wavelength increases.
Color is related to frequency through the electromagnetic spectrum, where different colors correspond to different wavelengths and frequencies of light. As the wavelength of light decreases, the frequency increases, resulting in different colors being perceived by the human eye. In the visible light spectrum, red light has a longer wavelength and lower frequency, while violet light has a shorter wavelength and higher frequency.
The lowest frequency audible to the human ear is around 20 Hz. Using the formula v = fλ, where v is the speed of sound (330 m/s) and f is the frequency (20 Hz), we can solve for the minimum wavelength, which is 16.5 meters.
Red light has a longer wavelength and lower frequency compared to blue light. Blue light has a shorter wavelength and higher frequency, which is why it appears bluer in color to the human eye.
The lowest frequency that the human ear can detect is that of 20Hertz.
The wavelength of ultrasound can be calculated using the formula: wavelength = speed of sound / frequency. For ultrasound in human tissue with a frequency of 3.5 million Hz, the speed of sound in tissue is around 1540 m/s. Therefore, the wavelength would be approximately 0.44 mm.
the highest frequency that can be heard by a human is 20000Hz
20Hz
The lowest frequency that a human can typically hear is around 20 Hz. Below this frequency, most people may not perceive the sound as a distinct pitch but rather as a sensation of pressure or vibration.
Its wavelength (or frequency).
The lowest natural frequency of sound is around 20 Hz, which is the lower limit of human hearing. Frequencies below this threshold are considered infrasound.